Functional aspects of the solution structure and dynamics of PAF--a highly-stable antifungal protein from Penicillium chrysogenum.

Penicillium antifungal protein (PAF) is a promising antimycotic without toxic effects on mammalian cells and therefore may represent a drug candidate against the often lethal Aspergillus infections that occur in humans. The pathogenesis of PAF on sensitive fungi involves G-protein coupled signalling followed by apoptosis. In the present study, the solution structure of this small, cationic, antifungal protein from Penicillium chrysogenum is determined by NMR. We demonstrate that PAF belongs to the structural classification of proteins fold class of its closest homologue antifungal protein from Aspergillus giganteus. PAF comprises five beta-strands forming two orthogonally packed beta-sheets that share a common interface. The ambiguity in the assignment of two disulfide bonds out of three was investigated by NMR dynamics, together with restrained molecular dynamics calculations. The clue could not be resolved: the two ensembles with different disulfide patterns and the one with no S-S bond exhibit essentially the same fold. (15)N relaxation dispersion and interference experiments did not reveal disulfide bond rearrangements via slow exchange. The measured order parameters and the 3.0 ns correlation time are appropriate for a compact monomeric protein of this size. Using site-directed mutagenesis, we demonstrate that the highly-conserved and positively-charged lysine-rich surface region enhances the toxicity of PAF. However, the binding capability of the oligosaccharide/oligonucleotide binding fold is reduced in PAF compared to antifungal protein as a result of less solvent-exposed aromatic regions, thus explaining the absence of chitobiose binding. The present study lends further support to the understanding of the documented substantial differences between the mode of action of two highly homologous antifungal proteins.

Antifungal protein PAF severely affects the integrity of the plasma membrane of Aspergillus nidulans and induces an apoptosis-like phenotype.

The small, basic, and cysteine-rich antifungal protein PAF is abundantly secreted into the supernatant by the beta-lactam producer Penicillium chrysogenum. PAF inhibits the growth of various important plant and zoopathogenic filamentous fungi. Previous studies revealed the active internalization of the antifungal protein and the induction of multifactorial detrimental effects, which finally resulted in morphological changes and growth inhibition in target fungi. In the present study, we offer detailed insights into the mechanism of action of PAF and give evidence for the induction of a programmed cell death-like phenotype. We proved the hyperpolarization of the plasma membrane in PAF-treated Aspergillus nidulans hyphae by using the aminonaphtylethenylpyridinium dye di-8-ANEPPS. The exposure of phosphatidylserine on the surface of A. nidulans protoplasts by Annexin V staining and the detection of DNA strand breaks by TUNEL (terminal deoxynucleotidyltransferase-mediated dUTP-biotin nick end labeling) gave evidence for a PAF-induced apoptotic-like mechanism in A. nidulans. The localization of reactive oxygen species (ROS) by dichlorodihydrofluorescein diacetate and the abnormal cellular ultrastructure analyzed by transmission electron microscopy suggested that ROS-elicited membrane damage and the disintegration of mitochondria played a major role in the cytotoxicity of PAF. Finally, the reduced PAF sensitivity of A. nidulans strain FGSC1053, which carries a dominant-interfering mutation in fadA, supported our assumption that G-protein signaling was involved in PAF-mediated toxicity.

Proper folding of the antifungal protein PAF is required for optimal activity.

The Penicillium chrysogenumantifungal protein PAF is secreted into the supernatant after elimination of a preprosequence. PAF is actively internalized into the hyphae of sensitive molds and provokes growth retardation as well as changes in morphology. Thus far, no information is available on the exact mode of action of PAF, nor on the function of its prosequence in protein activity. Therefore, we sought to investigate the effects of secreted PAF as well as of intracellularly retained pro-PAF and mature PAF on the sensitive ascomycete Aspergillus nidulans, and transformed this model organism by expression vectors containing 5'-sequentially truncated paf-coding sequences under the control of the inducible P. chrysogenum-derived xylanase promoter. Indirect immunofluorescence staining revealed the localization of recombinant PAF predominantly in the hyphal tips of the transformant Xylpaf1 which expressed prepro-PAF, whereas the protein was found to be distributed intracellularly within all segments of hyphae of the transformants Xylpaf2 and Xylpaf3 which expressed pro-PAF and mature PAF, respectively. Growth retardation of Xylpaf1 and Xylpaf3 hyphae was detected by proliferation assays and by light microscopy analysis. Using transmission electron microscopy of ultrathin hyphal sections a marked alteration of the mitochondrial ultrastructure in Xylpaf1 was observed and an elevated amount of carbonylated proteins pointed to severe oxidative stress in this strain. The effects induced by secreted recombinant PAF resembled those evoked by native PAF. The results give evidence that properly folded PAF is a prerequisite for its activity.

Active internalization of the Penicillium chrysogenum antifungal protein PAF in sensitive aspergilli.

The Penicillium chrysogenum antifungal protein PAF inhibits the growth of various filamentous fungi. In this study, PAF was found to localize to the cytoplasm of sensitive aspergilli by indirect immunofluorescence staining. The internalization process required active metabolism and ATP and was prevented by latrunculin B, suggesting an endocytotic mechanism.

Characterization of the Penicillium chrysogenum antifungal protein PAF.

The filamentous fungus Penicillium chrysogenum abundantly secretes the small, highly basic and cysteine-rich protein PAF ( Penicillium antifungal protein). In this study, the antifungal activity of PAF is described. PAF inhibited the growth of a variety of filamentous fungi, including opportunistic human pathogenic and phytopathogenic fungi, whereas bacterial and yeast cells were unaffected. PAF reduced the conidial germination and hyphal extension rates in a dose-dependent manner and induced severe changes in cell morphology that resulted in crippled and distorted hyphae and atypical branching. Growth-affected hyphae suffered from oxidative stress, plasma membrane leakage, and metabolic inactivity, which points to an induction of multifactorial effects in sensitive fungi. In contrast to other known antifungal proteins, the effects of PAF were only partially antagonized by cations.